Memory-mirroring control apparatus and memory-mirroring control method

ABSTRACT

When an update instruction for updating task data stored in a memory is transmitted through a transaction process performed by an application server, an active node apparatus generates, based on the update instruction, an update log indicating update contents of the task data stored in the memory, and then distributes, in a multicast manner, the generated update log to other standby node apparatuses each with a memory. With this, mirroring among the plurality of memories is controlled.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of application Ser. No. 12/533,882, filed Jul. 31, 2009, which is a continuation of PCT international application Ser. No. PCT/JP2007/053833 filed on Feb. 28, 2007 which designates the United States, the entire contents of which are incorporated herein by reference.

FIELD

The embodiments discussed herein are directed to a memory-mirroring control apparatus and a memory-mirroring control method for controlling data mirroring among a plurality of memories.

BACKGROUND

Conventionally, mission-critical systems typified by online systems for financial institutions and transportations are expected to achieve both “high reliability” and “high speed”.

Of these two, as a technology for achieving high reliability, a database-duplexing technology is generally used, such as cluster technology and replication technology.

FIG. 6 is a diagram of a conventional database cluster technology. As depicted in FIG. 6, the cluster technology is a technique of using cluster software to make a database redundant. With hardware being made in a redundant structure (“node #1”, “node #2”, “node #3”, . . . depicted in FIG. 6), the database is made highly reliable. This technology is adopted in, for example, a social infrastructure system. In this cluster technology, data maintenance is ensured by a shared disk (“disk” depicted in FIG. 6).

FIG. 7 is a diagram of a conventional database replication technology. As depicted in FIG. 7, the replication technology is a technique of conveying only the update result in a copy-source database (“node #1” in FIG. 7) to a copy-destination database (“node #2” in FIG. 7) for application, thereby making a replica of the database. This technology is adopted in, for example, a disaster control system. In this replication technology, File Transfer Protocol (FTP) transfer is used as a technique of transferring data to the copy destination.

On the other hand, as a technology for achieving high speed, an in-memory database has attracted attention in recent years. The in-memory database is a database that achieves an increase of the speed of accessing from an application to data and also achieves load distribution by storing data not in a disk but in a main memory (for example, refer to “Oracle TimesTen In-Memory Database” retrieved on Feb. 15, 2005 from the Internet <URL: http://otn.oracle.co.jp/products/timesten/>).

FIG. 8 is a diagram for explaining an in-memory database. As depicted in FIG. 8, in the in-memory database, user data stored in a hard disk resides in a memory. A task application updates the user data in the memory. Since an access is made onto the memory, high speed can be achieved.

In such an in-memory database, in addition to high speed, reliability as a database can be achieved by writing a log for insuring a transaction process into a disk. Such a technique of achieving reliability by using a log is used not only for the in-memory database but also for a conventional database with a disk as a storage medium. Examples of a log for use in this technique generally include a Before Image (BI) log and an After Image (AI) log.

The BI log is a log retaining the contents of the database before update, and is used mainly at the time of rolling back for restoring the contents of the database to a state before updating a transaction. By contrast, the AI log is a log retaining the contents of the database after update, and is used mainly for insuring the updated contents of the database about a transaction completed at the time of down recovery.

Here, down recovery is explained. In conventional down recovery, a transaction is recognized at the time of rebooting the database after the system goes down, and whether this transaction is valid or invalid is selected depending on the state of the transaction when the system goes down.

Specifically, in the conventional down recovery, a transaction in which a commit process had not yet been completed when the system went down is taken as invalid, and a data update performed during that transaction is also taken as invalid. On the other hand, a transaction in which a commit process had been completed when the system went down is taken as valid, and a data update performed during that transaction is also taken as valid.

FIG. 9 is a diagram for explaining conventional database down recovery. For example, as depicted in (1) of FIG. 9, it is assumed that a task application performs a commit process after updating user data “A” to “B”. At this time, as depicted in (2) of FIG. 9, a log indicating that the user data “A” has been updated to “B” is retained in a hard disk.

Then, as depicted in (3) of FIG. 9, it is assumed that a server goes down. In this case, when the database is rebooted, the user data in the database is restored to the latest state based on the information in the log. For example, as depicted in (4) of FIG. 9, the user data in the database is restored from “A” to “B”.

As such, in the conventional technology, high speed is achieved by using an in-memory database. Furthermore, a log indicating the updated contents of data (hereinafter, referred to as “update log”) is retained in a hard disk so as to allow data to be restored at the time of occurrence of a failure, thereby achieving high reliability.

In the conventional technology explained above, an update log is written in a disk so as to achieve high reliability. However, an access to the disk at the time of writing the update log disadvantageously impairs high-speed access to the database. To solve this problem, any access to the disk in the in-memory database has to be completely avoided.

However, to completely avoid any access to the disk, in place of the technology performed by using a disk for achieving high reliability, a new technology for achieving high reliability is required without using a disk. This requirement poses a serious problem for pursuing higher speed in mission-critical systems in the next generation.

SUMMARY

According to an aspect of the invention, an apparatus of controlling data mirroring among a plurality of memories includes an update-log generating unit that generates, when an update instruction for updating data stored in a predetermined memory is transmitted through a transaction process performed by an application, based on the update instruction, the update log indicating update contents of the data stored in the predetermined memory; and a memory-mirroring control unit that controls memory-mirroring among the memories by distributing, in a multicast manner, the generated update log to a plurality of other node apparatuses each with a memory.

The object and advantages of the invention will be realized and attained by means of the elements and combinations particularly pointed out in the claims.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are not restrictive of the invention, as claimed.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a diagram for explaining the concept of memory mirroring by node apparatuses according to an embodiment;

FIG. 2 is a functional block diagram of the configuration of a node apparatus according to the present embodiment;

FIG. 3 is a flowchart of the process procedure of the node apparatuses according to the present embodiment;

FIG. 4 is a functional block diagram of the configuration of a computer that executes a memory-mirroring program according to the present embodiment;

FIG. 5 is a system configuration diagram when a memory-mirroring control system according to the present invention is applied to a stock exchange system;

FIG. 6 is a diagram of a conventional database cluster technology;

FIG. 7 is a diagram of a conventional database replication technology;

FIG. 8 is a diagram for explaining an in-memory database; and

FIG. 9 is a diagram for explaining conventional database down recovery.

DESCRIPTION OF EMBODIMENTS

Preferred embodiments of the present invention will be explained with reference to accompanying drawings. Note that the embodiments explained below are to control data mirroring among a plurality of memories in node apparatuses that each retain various task data in an in-memory database at the backend of an application server that provides a predetermined task service.

First, the concept of memory mirroring by node apparatuses according to the present embodiment is explained. FIG. 1 is a diagram for explaining the concept of memory mirroring by node apparatuses according to the present embodiment. As depicted in FIG. 1, node apparatuses 10 ₁ to 10 ₃ according to the present embodiment are set in a manner such that the node apparatus 10 ₁ operates as active and the node apparatuses 10 ₂ and 10 ₃ operate as standbys. These node apparatuses are connected to each other via a network not depicted, and are also communicably connected to an application server 20 that performs various transaction processes by using a predetermined task application.

In this configuration, the node apparatus according to the present embodiment has a main feature such that, when an update instruction for updating task data stored in a memory is transmitted through a transaction process performed by the application server 20, the node apparatus generates, based on that update instruction, an update log indicating the updated contents of the task data stored in the memory and distributes, in a multicast manner, the generated update log to other node apparatus each with a memory, thereby controlling data mirroring among a plurality of memories.

Specifically, when an instruction for updating task data is distributed in a multicast manner through a transaction process performed by the application server 20 (refer to (1) in FIG. 1), the node apparatus 10 ₁ generates, based on that update instruction, an update log indicating the updated contents of the task data, and retains the update log in its own memory (refer to (2) in FIG. 1). On the other hand, the node apparatuses 10 ₂ and 10 ₃ do not perform any process even when the update instruction is similarly distributed thereto, and discard the distributed update instruction (refer to (3) and (4) in FIG. 1).

Thereafter, when commit information indicating that the transaction process has been completed is transmitted from the application server 20, the node apparatus 10 ₁ distributes the generated update log to other node apparatuses that belong to the same task group (here, the node apparatuses 10 ₂ and 10 ₃) in a multicast manner (refer to (5) in FIG. 1). The node apparatuses 10 ₂ and 10 ₃ receiving the update log each retain the received update log in its own memory, and reply to the node apparatus 10 ₁ with an acknowledgement (ACK) response indicating that the update log has been received (refer to (6) and (7) in FIG.

When a reply with an ACK response is sent from the node apparatuses 10 ₂ and 10 ₃, the node apparatus 10 ₁ performs real updating of the task data stored in the memory based on the update log retained in the memory (refer to (8) in FIG. 1). On the other hand, the node apparatuses 10 ₂ and 10 ₃ performs real updating of the task data stored in their respective memories based on the update log retained in their respective memories at a predetermined timing asynchronous with the updating of the task data in the node apparatus 10 ₁ (refer to (9) and (10) in FIG. 1).

With this feature, the node apparatuses 10 ₁, 10 ₂, and 10 ₃ according to the present embodiment allow the same task data to be retained in the memories of the plurality of node apparatuses, thereby achieving high reliability of the in-memory database without using a disk.

Next, the configuration of the node apparatuses 10 ₁ to 10 ₃ according to the present embodiment is explained. Note that since these node apparatuses 10 ₁ to 10 ₃ have a similar configuration, the node apparatus 10 ₁ is taken as an example for explanation. FIG. 2 is a functional block diagram of the configuration of the node apparatus 10 ₁ according to the present embodiment. As depicted in FIG. 2, the node apparatus 10 ₁ includes a transaction-communication control unit 11, a node-to-node communication control unit 12, a memory 13, and a control unit 14.

The transaction-communication control unit 11 is a processing unit that controls transmission and reception of data exchanged with the application server 20. Specifically, when the node apparatus 10 ₁ is set as active, upon receiving a task-data update instruction distributed in a multicast manner from the application server 20, the transaction-communication control unit 11 passes the received update instruction to a log generating unit 14 a, which will be explained further below.

Also, when receiving from the application server 20 commit information indicating that the transaction process has been completed, the transaction-communication control unit 11 passes the received commit information to a log-distribution control unit 14 b, which will be explained further below.

Furthermore, when notified by a data updating unit 14 c, which will be explained further below, that real updating of task data 13 b stored in the memory 13 has been completed, the transaction-communication control unit 11 transmits to the application server 20 commit information indicating that an update of the task data has been completed.

On the other hand, when the node apparatus 10 ₁ is set as standby, upon receiving a task-data update instruction from the application server 20, the transaction-communication control unit 11 discards the received update instruction, and also notifies the data updating unit 14 c, which will be explained further below, that the update instruction has been received.

The node-to-node communication control unit 12 is a processing unit that controls transmission and reception of data exchanged with another node apparatus. Specifically, when the node apparatus 10 ₁ is set as active, the node-to-node communication control unit 12 distributes an update log 13 a passed from the log-distribution control unit 14 b, which will be explained further below, to another node apparatus in a multicast manner. Also, when receiving from another node apparatus an ACK response indicating that an update log has been received, the node-to-node communication control unit 12 notifies the data updating unit 14 c, which will be explained further below, that the ACK response has been received.

On the other hand, when the node apparatus 10 ₁ is set as standby, upon receiving an update log distributed in a multicast manner from another node apparatus set as active, the node-to-node communication control unit 12 passes the received update log to the log-distribution control unit 14 b, which will be explained further below, and also replies to the active node apparatus with an ACK response indicating that the update log has been received.

The memory 13 is a storage unit that has stored therein various data and programs, such as the update log 13 a and the task data 13 b, which are examples of those relating to the present invention. Here, the update log 13 a is data indicating the updated contents of the task data 13 b, and is generated based on the update instruction distributed by the application server 20. Also, the task data 13 b includes various task data regarding task services provided by the application server 20, and is managed by an in-memory database not depicted.

The control unit 14 is a control unit that controls over the entire node apparatus 10 ₁, and includes the log generating unit 14 a, the log-distribution control unit 14 b, and the data updating unit 14 c, which are examples of those relating to the present invention.

The log generating unit 14 a is a processing unit that generates the update log 13 a indicating the updated contents of the task data 13 b. Specifically, when the task-data update instruction is passed from the transaction-communication control unit 11, the log generating unit 14 a generates the update log 13 a based on that update instruction, and causes the generated update log 13 a to be stored in the memory 13.

The log-distribution control unit 14 b is a processing unit that distributes the update log 13 a generated by the log generating unit 14 a to other node apparatuses and causes an update log distributed from another node apparatus to be stored in the memory 13, thereby controlling data mirroring among the plurality of memories.

Specifically, when the node apparatus 10 ₁ is set as active and commit information indicating that the transaction process has been completed is passed from the transaction-communication control unit 11, the log-distribution control unit 14 b passes the update log 13 a retained in the memory 13 to the node-to-node communication control unit 12, thereby distributing the update log 13 a to other node apparatuses in a multicast manner.

Note that when an abnormality is detected in the transaction process before commit information is transmitted, the log-distribution control unit 14 b discards the update log 13 a retained in the memory 13. With this, an update of the task data 13 b by the transaction process where an abnormality has occurred can be controlled so that the task data of other node apparatuses does not reflect this update.

On the other hand, when the node apparatus 10 ₁ is set as standby and an update log is passed from the node-to-node communication control unit 12, the log-distribution control unit 14 b causes this update log to be stored in the memory 13.

The data updating unit 14 c is a processing unit that performs real updating of the task data 13 b based on the update log 13 a retained in the memory 13 and asynchronously with the updating of the task data in each of the other node apparatuses.

Specifically, when the node apparatus 10 ₁ is set as active, upon being notified by the node-to-node communication control unit 12 that ACK responses have been received from all node apparatuses with an update log distributed thereto from the log-distribution control unit 14 b, the data updating unit 14 c performs real updating of the task data 13 b based on the update log 13 a retained in the memory 13. Then, after the real updating of the task data 13 b is completed, the data updating unit 14 c notifies the transaction-communication control unit 11 of commit information indicating that the update of the task data has been completed, thereby transmitting the commit information to the application server 20.

On the other hand, when the node apparatus 10 ₁ is set as standby, upon being notified by the transaction-communication control unit 11 that a task-data update instruction has been received, the data updating unit 14 c performs real updating of the task data 13 b based on the update log 13 a retained in the memory 13.

As such, the update of the task data performed in the node apparatus set as active and the update of the task data performed in the node apparatus set as standby are performed asynchronously.

Next, the process procedure of the node apparatus according to the present embodiment is explained. FIG. 3 is a flowchart of the process procedure of the node apparatuses according to the embodiment. In FIG. 3, the process procedure of each of the node apparatuses 10 ₁ to 10 ₃ depicted in FIG. 1 is depicted, and it is assumed that the node apparatus 10 ₁ is set as a node apparatus as active (hereinafter, referred to as an “active node”) and the node apparatuses 10 ₂ and 10 ₃ as node apparatuses as standby (hereinafter, referred to as “standby nodes”).

As depicted in FIG. 3, when a task-data update instruction is first distributed from the application server 20 in a multicast manner (Step S101), in the node apparatus 10 ₁, the transaction-communication control unit 11 receives the distributed update instruction, and the log generating unit 14 a generates the update log 13 a based on the update instruction (Step S102).

On the other hand, in the node apparatuses 10 ₂ and 10 ₃, each transaction-communication control unit receives the distributed update instruction, and discards the received update instruction (Steps S103 and S104).

Thereafter, when commit information (COMMIT) is transmitted (issued) from the application server 20 (Step S105), in the node apparatus 10 ₁, the transaction-communication control unit 11 receives the transmitted commit information, and the log-distribution control unit 14 b distributes the update log 13 a to the standby nodes (the node apparatuses 10 ₂ and 10 ₃) in a multicast manner (Step S106).

When the update log 13 a is distributed, in the node apparatuses 10 ₂ and 10 ₃, each node-to-node communication control unit receives the update log 13 a, and replies with an ACK response to the active node (the node apparatus 10 ₁) (Steps S107 and S108).

Then, when a reply with an ACK response is sent from all standby node apparatuses, in the node apparatus 10 ₁, the node-to-node communication control unit 12 receives the respective ACK responses (Step S109), the data updating unit 14 c performs real updating of the task data 13 b retained in the memory 13 (Step S110), and the transaction-communication control unit 11 transmits (returns) commit information (COMMIT) to the application server 20 (Step S111).

Then, in the node apparatuses 10 ₂ and 10 ₃, each data updating unit 14 c performs real updating of the task data retained in its own memory asynchronously with the update of the task data in the node apparatus 10 ₁ (active node) explained above (Steps S112 and S113).

As explained above, in the present embodiment, when an update instruction for updating the task data stored in the memory is transmitted through a transaction process performed by the application server 20, the log generating unit 14 a generates, based on this update instruction, the update log 13 a indicating the updated contents of the task data 13 b stored in the memory 13, and the log-distribution control unit 14 b then distributes the generated update log 13 a to other node apparatuses each with a memory in a multicast manner, thereby controlling task-data mirroring among the plurality of memories. Therefore, the same task data can be retained in the plurality of memories, thereby achieving high reliability of the in-memory database without using a disk.

Also, in the present embodiment, the data updating unit 14 c performs, based on the generated update log 13 a, real updating of the task data 13 b stored in the memory 13 asynchronously with the update of the task data performed in other node apparatuses based on the distributed update log 13 a. Therefore, mirroring among the memories can be performed without affecting a response to the transaction process performed by the application server 20.

Furthermore, in the present embodiment, when a reply with an ACK response indicating that the update log 13 a has been received is sent from all node apparatuses to which the update log 13 a has been distributed, the data updating unit 14 c performs, based on the generated update log 13 a, real updating of the task data 13 b stored in the memory 13. Therefore, after it is confirmed that the update log 13 a has reached all node apparatuses, the task data 13 b stored in the memory 13 can be updated. With this, reliability of the in-memory database can be further increased.

Still further, in the present embodiment, when commit information indicating that the transaction process has been completed is sent from the application server 20, the log-distribution control unit 14 b distributes the update log 13 a to other node apparatuses in a multicast manner. When an abnormality is detected in the transaction process before the commit information is transmitted, the update log is discarded. Therefore, mirroring among the memories can be performed only when the transaction process normally ends, thereby minimizing a range of influence when an abnormality occurs in the transaction process.

Still further, in the present embodiment, the log-distribution control unit 14 b causes the update log distributed from other node apparatuses in a multicast manner to be stored in the memory 13. Also, when a task-data update instruction is distributed in a multicast manner through a transaction process by the application server 20, the task data 13 b stored in the memory 13 is subjected to real updating based on the stored update log. Therefore, by using the update instruction distributed in a multicast manner from the application server 20, the update of the task data in each node apparatus can be controlled, thereby efficiently mirroring among the memories.

Still further, according to the present embodiment, the log-distribution control unit 14 b causes the update log distributed from other node apparatuses in a multicast manner to be stored in the memory 13. Also, when the update log is received, the task data 13 b stored in the memory 13 is subjected to real updating based on the update log already stored at the time of receiving the update log. Therefore, by using the update log distributed in a multicast manner from other node apparatuses, the data update in each node apparatus can be controlled, thereby efficiently mirroring among the memories.

Here, the case has been explained in the present embodiment in which, when the node apparatus 10 ₁ is set as standby, the data updating unit 14 c updates the task data 13 b upon the update instruction distributed in a multicast manner from the application server 20. However, this is not meant to restrict the present invention.

For example, when receiving an update log distributed in a multicast manner from another node apparatus set as active, the node-to-node communication control unit 12 may notify the data updating unit 14 c that the update log has been received. When accepting the notification, the data updating unit 14 c may perform real updating of the task data 13 b based on the update log 13 a already retained in the memory 13 at the time of acceptance.

With this, by using the update log distributed in a multicast manner, the data update in each node apparatus can be controlled, thereby efficiently mirroring among the memories.

Still further, while the case of the node apparatus for memory mirroring has been explained in the present embodiment, a memory-mirroring program having functions similar to those of the node apparatus can be obtained by achieving the structure of the node apparatus with software. Here, a computer that executes such a memory-mirroring program is explained below.

FIG. 4 is a functional block diagram of the configuration of a computer that executes a memory-mirroring program according to the present embodiment. As depicted in FIG. 4, a computer 100 includes a Random Access Memory (RAM) 110, a Central Processing Unit (CPU) 120, a Hard Disk Drive (HDD) 130, a Local Area Network (LAN) interface 140, an input/output interface 150, and a Digital Versatile Disk (DVD) drive 160.

The RAM 110 is a memory that has stored therein programs and execution progress results of these programs and others. The RAM 110 corresponds to the memory 13 depicted in FIG. 2, and also has stored therein the update log 13 a and the task data 13 b, for example. The CPU 120 is a central processing unit that reads a program from the RAM 110 for execution.

The HDD 130 is a disk device that has programs and data stored therein. The LAN interface 140 is an interface for connecting the computer 100 to another computer via a LAN, connecting the computer 100 that operates as a node apparatus to the application server 20 and another node apparatus.

The input/output interface 150 is an interface for connecting an input device, such as a mouse and keyboard, and a display device. The DVD drive 160 is a device that reads from and writes in a DVD.

A memory-mirroring program 111 executed on this computer 100 is stored in a DVD, and is read from the DVD by the DVD drive 160 to be installed on the computer 100.

Alternatively, the memory-mirroring program 111 is stored, for example, in a database in another computer system connected via the LAN interface 140, and is read from this database to be installed on the computer 100.

The installed memory-mirroring program 111 is then stored in the HDD 130, is read onto the RAM 110, and is then executed by the CPU 120 as a memory-mirroring process 121.

Still further, for convenience of explanation, the case has been explained in the present embodiment in which two node apparatuses are set as standby. However, this is not meant to restrict the present invention. Alternatively, only one node apparatuses may be set as standby, or three or more node apparatuses may be set as such. That is, in the present embodiment, depending on reliability requirements, a plurality of node apparatuses can be set as standby, thereby performing database redundancy.

In the node apparatus set as standby, the task data having the same contents as that of the node apparatus set as active is retained. Therefore, even when the task data of the active node apparatus may not be referred to due to a network failure or the like, the task data can be checked by referring to the database in the standby node apparatus.

Still further, in the node apparatus according to the present embodiment, when a failure occurs, a predetermined recovery processing unit can be used to perform recovery as follows.

First, when a failure occurs in the active node apparatus, the recovery processing unit stops the active node apparatus, and also newly sets any one of the standby node apparatuses as active. At this time, the recovery processing unit sets the node apparatus newly set as active in a manner such that the update log is not distributed to the node apparatus where the failure has occurred.

Specifically, from multicast addresses serving as a reference for distribution of the update log by the node-to-node communication control unit 12, the recovery processing unit excludes the address of the node apparatus where a failure has occurred.

Subsequently, with reference to the memory of the node apparatus newly set as active and the memory of other standby node apparatus(es), the recovery processing unit checks the state of reflecting the update log onto the task data. When it is confirmed that the update log has been correctly reflected on all node apparatuses, the recovery processing unit transmits, from the node apparatus newly set as active to the application server 20, commit information indicating that the updating the task data has been completed.

Here, if there is a node apparatus where the update log is not correctly reflected on the task data, the recovery processing unit rolls back the task data where the update log has already been reflected, thereby insuring consistency of the task data in the memory. Then, upon completion of the series of recovery processes, the recovery processing unit uses the node apparatus newly set as active to restart the task.

On the other hand, when a failure occurs in any standby node apparatus, the recovery processing unit stops that standby node apparatus, and sets the active node apparatus so that it does not distribute the update log to the node apparatus where the failure has occurred. Specifically, from the multicast addresses serving as a reference for distribution of the update log by the node-to-node communication control unit 12, the recovery processing unit excludes the address of the node apparatus where a failure has occurred.

Even while the recovery processing unit is performing a recovery process, the active node apparatus continuously operates. Therefore, when a failure occurs in any standby node apparatus, the transaction process by the application server 20, that is, the task service provided by the application server 20 is not affected by the recovery process.

Still further, among the processes explained in the present embodiment, all or part of the processes explained as being automatically performed can be manually performed, or all or part of the processes explained as being manually performed may be automatically performed through a known method.

In addition, the process procedure, the control procedure, specific names, and information including various data and parameters explained in the specification and depicted in the drawings can be arbitrarily changed unless otherwise specified.

Still further, each component of each apparatus depicted is conceptual in function, and is not necessarily physically configured as depicted. That is, the specific patterns of distribution and unification of the components are not meant to be restricted to those depicted in the drawings. All or part of the components can be functionally or physically distributed or unified in arbitrary units according to various loads and the state of use.

Still further, all or arbitrary part of the process functions performed in each component can be achieved by a CPU and a program analyzed and executed on that CPU, or can be achieved as hardware with a wired logic.

EXAMPLE

An example in a stock exchange system is explained below. FIG. 5 is a system configuration diagram when a memory-mirroring control system according to the invention is applied to a stock exchange system.

First, reference numeral 1001 denotes a market management server, which corresponds to the application server 20 in the embodiment explained above. In this market management server 1001, based on schedule information stored in a schedule management 10021 of a DB server 1002, a status instructing unit 10011 performs multicast communications of a status instruction through the procedure explained in the embodiment explained above via a network 1003 (in FIG. 5, referred to as highly-reliable multicast 10012).

Also, when the market management server 1001 receives regulation instruction information output from a regulation instructing unit 10051 of an in-house web server 1005 upon a regulation instruction from a trading management terminal 1004, a status instruction 10013 in the market management server 1001 performs multicast communications of the regulation instruction through the procedure explained in the embodiment above through the network 1003 (in FIG. 5, referred to as highly-reliable multicast 10014).

Reference numeral 1006 denotes a participant gateway that provides various notifications to participants in stock exchange. When a participant liaison adaptor 10061 receives information about various highly-reliable multicasts from the market management server 1001, the participant liaison adaptor 10061 determines whether a notification is to be provided to the participants. As for multicast information for which a notification is determined to be provided, that multicast information is transmitted as a market management telegraphic message to a participant server 1007.

Reference numeral 1008 denotes a trading server, including an order Durable Archive Memory (DAM) 10081, a special quote DAM 10082, and a board DAM 10083. The order DAM 10081, the special quote DAM 10082, and the board DAM 10083 are node apparatus groups depicted as the node apparatuses 10 ₁, to 10 ₃ by units of task group explained above.

That is, when receiving the highly-reliable multicasts 10012 and 10014 from the market management server 1001, the order DAM 10081, the special quote DAM 10082, and the board DAM 10083 each determine whether the received information relates to itself, and perform a process through the procedure depicted in FIG. 3.

In this manner, since all instructions to each DAM and participant are made through multicast transmission, an error in status-changing timing and notification timing can be minimized. Also, since the process of the trading server 1008 and notification to the participant server 1007 via the participant gateway 1006 are concurrently performed, the participants can be notified of a status change and the like at higher speed.

Furthermore, with each DAM performing the procedure of the embodiment of the present invention, a highly-reliable process can be performed at high speed.

According to an embodiment, an effect can be achieved such that the same data can be retained in a plurality of memories, thereby achieving high reliability of the in-memory database without using a disk.

Also, according to the embodiment, an effect can be achieved such that mirroring among memories can be performed without affecting a response to the transaction process performed by the application.

Furthermore, according to the embodiment, an effect can be achieved such that data stored in a memory can be updated after it is confirmed that an update log has reached all node apparatuses, thereby further increasing reliability of the in-memory database.

Still further, according to the embodiment, an effect can be achieved such that mirroring among memories can be performed only when a transaction process normally ends, thereby minimizing a range of influence when an abnormality occurs in the transaction process.

Still further, according to the embodiment, an effect can be achieved such that data update in each node apparatus can be controlled by using an update instruction distributed in a multicast manner, thereby efficiently mirroring among memories.

Still further, according to the embodiment, an effect can be achieved such that data update in each node apparatus can be controlled by using an update log distributed in a multicast manner, thereby efficiently mirroring among memories.

All examples and conditional language recited herein are intended for pedagogical purposes to aid the reader in understanding the invention and the concepts contributed by the inventor to furthering the art, and are to be construed as being without limitation to such specifically recited examples and conditions, nor does the organization of such examples in the specification relate to a showing of the superiority and inferiority of the invention. Although the embodiments of the present inventions have been described in detail, it should be understood that the various changes, substitutions, and alterations could be made hereto without departing from the spirit and scope of the invention. 

1. A computer readable storage medium containing instructions for controlling data mirroring among a plurality of memories, the instructions, when executed by a computer, cause the computer to perform: generating, when an update instruction for updating data stored in a predetermined memory is transmitted through a transaction process performed by an application, based on the update instruction, the update log indicating update contents of the data stored in the predetermined memory; and controlling memory-mirroring among the memories by distributing, in a multicast manner, the generated update log to a plurality of other node apparatuses each with a memory. 